Measuring and control apparatus



Sept. 25, 1945.

H. S. JONES MEASURING AND CONTROL APPARATUS Filed Nov. 4, 1942 2 Sheets-Sheet l INVENTOR.

HARRY S. JONES AT RNEY p 1945- H. s. JONES MEASURING AND CONTROL APPARATUS Filed Nov. 4, 1942 2 Sheets-Sheet 2 FIG. 3.

FIG.

INVENTOR. HARRY S. JONES ATTORNEY.

Patented 25, 1945 UNITED -S. 'lATE Harry S. Jones, Washington, D. 0., alsignor to The Brown Instrument Company, Philadelphia,

Pa., a corporation of Pennsylvania.

' g Application November 4.1m, Serial sums 1 Claims. (01. ire-m) 'lhe present invention relates to an improved method ofand apparatus for making accurate measurements of minute electrical currents orvoitages.

- A general object of invention is to provide] a method of eliminating the sheets of stray electrical fields or spurious electrical. effects upon I the operation of apparatus designed for accurately measuring the magnitude or changes in magnitude of minute electrical currents or volt 3888.

A specific object of the invention is to provide ously induced alternating currents upon the operation of apparatus designed for making accurate measurements of the magnitude and changes in magnitude of minute unidirectionalelectrical currents flowing in lowresistance circuits.

A more specific object of the invention is to provide a self balancing potentiometer instrument which incorporates the approved practices of the art in respect to many of its features and which embodies provisions for eliminating the eifects of stray electrical fields or spurious electrical currents upon the operation 01 the instrument and thereby upon thev measurement obtained. V

In making accurate measurements of small unidirectional electrical currents flowing in low resistance circuits. for example, in potentiometric measuring circuits utilized for measuring the eiectromotive forces produced by athermocouple, considerable dimculty has been encountered in the prior art because of the introduction of extraneous fluctuating or alternating currents into the potentiometric measuring circuits. Such fluctuating or alternating currents may be introduced into the potenticmetricmeasuring circuits by induction from stray alternating current fields in the vicinit of the apparatus, or may be introduced therein by means of abnormal circuit paths established between the thermocouple and the potentiometrie measuring circuit and including an alternating current source.

Accordingly, it is a specific object or the pres-.

- ent invention to provide simple and emcient means for eliminating the eflects or such extraneously induced alternating currents or spurious electrical effects upon the operation of potentiometric measuring apparatus arranged for accurately measuring the magnitude and changes in magnitude of minute unidirectional electrical currents.

' a method of eliminating the eifects of extranea? 'teriite-iny invention are pointed out with particularity inthe claims annexed to and forming a 3 part of this specification. For 0. better understanding of the invention, however, its advantsges and specific objects obtained with its use,

reference should be had to the accompanying drawings and descriptive matter in which I have illustrated and described a preferred embodiment of the invention.

of the drawings:

Fig. l is a diagrammatic illustration of one embodiment of my invention; and

Figs. 2, 3', 4 and 5 are graphs illustrating vectorially the operation Fi 1.-

1 Referring to Fig. 1 of the drawings there is illustrated in schematic form an electronic device generally designated'by the reference character l for producing effects in accordance with the extent of unbalance of a potentiometric measuring circuit 2 which controls the operation The potentiometric circuit 2 is unbalanced in accordance with the variations in a quantity to be measured and because of the small magnitude of the unbalanced electromotive forces produced in the potentio- I metric measuring circuit it is not practicable nor produced disordlng the temperature of a furnace (not shown). in the interior of which a thermocouple 3 is arranged which is responsive to slight changes in the temperature oi the furnace. The thermocouple which may be located at a distance from the remainders! the potentiometric messuring circuit has its terminals connected by a tiometric circuit 2 includes a slidewire resistance 1 and an associated contact I which is adapted to be moved along the length of the slidewire t. It will be understood that the potentiometric cirwit 2 illustrated schematically in the drawings may be of any suitable type such as the Brown potentiometric type disclosed in Patent 2,150,502 issued to T. R. Harrison, E. H. Grauel and J. E. Kessler on March 14, 1939. The movable contact I is attached to a suitable carrier which, for example, may be in the form of an internally threaded nut 8 adapted to ride on a screw threaded rod 9 which is rotated in one direction or the The various features of novelt which'charac. other under control or the thermocouple 8. A

oaries r of the arrangement of 1 along the slidewire resistances 8 and I2 by the operation of the reversible electrical motor it which is shown as having its rotor 23 mechanically coupled to the threaded shaft 9 on which resistance i2 has one end connected by the conductor A to one terminal of the thermocouple 3 and is employed for the purpose of avoiding measurement inaccuracies due to variations in resistance to the flow of current generated by the thermocouple 3 which would otherwise result from variations in the relative resistances of the portions of the resistance 8 at opposite sides of the point H. The other terminal of the thermocouple 3 is connected by means of the conductor to the center tapon the primary winding i3 of a transformer ii having a secondary winding to. One end terminal of the primary winding 93 is connected to a contact 16 of a current interrupting device designated generally at W and the other end terminal of the primary winding 83 is connected to a contact 18 of the device ii. 'The current interrupting device ll may be of the type disclosed in the copending Harrison et a1; Patent 2,300,742 issued November 3, 1942, from application, Serial No. 240,594, filed November 15, 1938, and includes a vibrating reed i9 and an energizing winding 20 in addition to the contacts i8 and it. The vibrating reed is positioned between the contacts 18 and i8 and is adapted to engage the latter contacts in alternation. The vibrating reed I9 is connected by a conductor 25 to the point 22 of the potentiometric measuring circuit 2.

With the arrangement disclosed in the drawing the flow and the direction of flow of current through the circuit branch irom the point 22 of the potentiometric measuring circuit 2 to the current interrupting device ll, the transformer it, the thermocouple 3, and the bridging contact 7 to the point H on the measuring circuit 2 depends upon the relation between the electromotive force produced by the thermocouple 3 and the potential difierence between the potentiometric circuit points ii and 22. The thermocouple S is so connected to the potentiometric circuit that the electromotive force of the thermocouple opposes the potential difiference between the points ii and 22. The potential difierence between the points ii and 22 is increased and decreased by move ment of the contact 7 to the left and to the right, respectively. With suitable adjustments of the contact I the potential diiierence between the points it and 22 will be equal and opposite to the electromotive force produced by the thermocouple 3 and no current will flow through the above mentioned circuit branch includin the current interrupting device ii, the transformer l4 and the thermocouple 3. On an increase in the thermocouple electromotive force above the potential difierence between the points i i and 22 current will flow in one direction through the interrupter ii and the transformer primary winding it and such current flow may then be eliminated by a suitable adjustment of the bridge contact 1 to the left. Conversely, when the electromotive force of the thermocouple 8 falls below the potential difierence between the potentithe carriage B which supports the bridging contact 7 is mounted. The reversible electrical motor 10 has a pair of terminals 24 and 25 which are connected to the output circuit of the electronic device I and also has a pair of terminals 26 and 27 which are connected to the secondary winding 28 of a transformer 29 having a' primary winding 36 which is energized from a suitable source of alternating current produced in the manner described hereinafter. The transformer 29 is also provided with secondary windings 3i and 32.

For its intended use the motor Iii may be of the form diagrammatically shown in the drawings and comprising the rotor 23 and two pairs of oppositely disposed fleld poles (not shown) on one pair of which a winding 33 is wound and on the other pair of which a winding 36 is wound. Windin 33 has its terminals connected to the motor terminals 28 and Ti and is supplied with energizing current from the transformer secondary winding 28 through a condenser 38 of suitable value. Due to the action of the condenser 36 the current which flow through the motor winding 33 will lead the voltage produced across the terminals of the transformer secondary windings 28 by approximately The current supplied to the winding 36 of the motor lit by the electronic device 9 is in phase with or is displaced with respect to the voltage produced across the terminals of the transformer secondary winding 28 and establishes the field in rotor 23 which is displaced 90 in one direction or the other with respect to that established therein by the winding 83. Reaction between the field set up by the winding 83 with that set up by winding 36 establishes a rotating field in the rotor which rotates in one direction or the other depending upon whether the winding 85 is energized with current in phase with the voltage produced across the terminals of the transformer secondary winding 23 or displaced 180 in phase therewith, and thereby, as is explained in detail hereinafter, in accordance with the direction of unbalance of the potentiometric measuring cir-- cuit 2. The direction and duration of rotation of the motor i6 is controlled in accordance with the direction and extent of unbalance of the potentiometric measuring circuit 2 so that on rotation of the motor the bridging contact is adjusted in the proper direction to rebalance the pctentiometric circuit 2.

If desired, a pen 3% may be mounted on the carriage 3 which carries bridging contact 7 and arranged in cooperative relation with a recorder chart 3? to thereby provide a continuous record of the temperature to which the thermocouple 3 is subjected. The chart 3? may be a strip chart as shown and is adapted to be driven in any convenient manner as, for example, by a unidirectional electrical motor 38 through suitable gearlug (not shown) so that a record of the temperature to which the thermocouple 3 is subjec ed will be recorded as a continuous line on the chart 31.

The current interrupting device I! illustrated schematically in the drawings operates to convert the potentiometric unbalanced unidirectional currents into alternating currents in the transformer secondary winding 15 which are capable of being readily amplified and comprises the vibrating reed I! for operating a contact 39 with respect to the relatively fixed contacts is and 18. The vibrating reed i9 is vibrated under the influence of the winding 2|] which is connected to the winding 32 of the transformer 29 by conductors 40 and 4| and is supplied with alternating current therefrom. A permanent magnet 42 associated with the vibrating reed l9 isgprovided for polarizing and synchronizing purposes.

Fundamentally, the current interrupting device I1 is a polarized switching mechanism, the

operating winding 20 and the permanent magnet 42 cooperating to vibrate the vibrating reed I! at the same frequency as the frequency of the alternating voltage supplied by the transformer secondary winding 32. For purposes of illustration it may be assumed that the contact 39 is in engagement with the contact l6 during the first half cycle of the alternating voltage supplied the winding 20, for example, when the upper terminal of the winding 20, is positive with respect to the lower terminal thereof, and that the contact 33 is in engagement with the contact 18 during the second half cycle when the upper terminal of the winding 20 is negative with respect to the lower terminal thereof.

When the potentiometric measuring circuit 2 is balanced no current flows in the circuit between the potentiometer points I l and 22 and including the contacts 39, I6 and Hi, the transformer primary Winding l3 and the thermocoupie 3. When the temperature to which the thermocouple 3 is subjected increases the unbalanced unidirectional current in the potentiometer circuit flows in the direction from the potentiometer point 22 through the conductor 2! to the current interrupting device ll, transformer primary winding [3, the thermocouple 3 and the bridging contact I to the potentiometer point ll. Conversely, when the temperature to which the thermocouple 3 is subjected decreases the unbalanced unidirectional current in the potcntiorneter circuit flows in the opposite direction, namely from the potentiometer point H to the potentiometer point 22.

When the temperature to which the therrnocouple 3 is subjected increases, during the first half cycle of the alternating voltage supplied to the winding 20 of the device I! the unbalanced potentiometer unidirectional current flows from the potentiometer point 22 through the conduc tor 2| to the reed l5, contact 15 to the lower end of the transformer primary winding l3 through the lower half of the winding :3 to the conductor 5, thermocouple 3. conductor 4 and the bridging contact I to the potentiometer point i i. This current flow through the lower half of the trans-- former primary winding 14 operates to induce a voltage in the transformer secondary winding 55 causing the upper terminal of the latter to be positive with respect to the lower terminal, for

example. During the second half of the alternating voltage supply to the winding 26 the HR balanced unidirectional potentiometer currents flow from the point 22 of the potentiometer circult through the conductor 2i to the vibrating reed is, contact 39, contact it to the upper ter minal of the transformer primary winding 13, through the upper half of the winding II to the conductor 5, to conductor 4 and the bridging contact I to the potentiometer point II. This flow of current in the upper half of the transformer primary winding l3 causes the induction of a voltage in the transformer secondary winding 15 of the polarity to make the upper terminal of the winding (5 negative with respect to the lower terminal. Therefore, it will be seen that with the arrangement shown and described an alternating voltage is produced across the transformer secondary winding i5 which is in phase with the alternaitng voltage supplied the winding of the current interrupting device I! and is of the same frequency as supplied the winding 20.

Upon a decrease in the temperature to which the thermocouple 3 is subjected, the unbalanced potentiometer unidirectional currents flow from the potentiometer point I l to the point 22. During the first half cycle of the alternating voltage supplied the winding 20 current flows from the potentiometer point H through the bridging contact l, resistance l2, conductor 4, thermocouple 3, conductor 5, the lower half of the transformer secondary winding l3 to the contact 48 of the device H, the vibrating reed l9 and conductor 2| to the potentiometer point 22. This flow of current through the lower half of the transformer primary winding l3 causes the induction of a voltage in the transformer secondary winding l5 of the proper polarity to cause the upper terminal of the winding l5 to become negative with respect to the lower terminal. During the second half of the alternating voltage supplied the winding 20 the unbalanced potentiometer unidirectional current flows from the potentiometer point ll through the bridging contact I, resistance l2, conductor 4, the thermocouple 1, conductor 5, the upper half of the transformer primary winding [3, contact l8, contact 39, the vibrating reed l9, contact 2| to the potentiometer point 22. This current flow through the upper half of transformer primary winding I3 operates to induce a voltage in the transformer secondary winding 15 to cause the potential of the upper terminal to become positive with respect to the lower terminal. Accordingly, when the temperature to which the thermocouple 3 is sub- Jected decreases, an alternating voltage of the opposite phase is produced across the transformer secondary winding i5.

Summarizing, when the potentiometric measuring circuit 2 is balanced there is no current .i flow through the transformer primary winding l3 and hence no voltage is induced in the transformer secondary winding I5. Upon an increase in the temperature to which the thermocouple 3 is subjected the flow of potentiometer unbalanced current through the transformer primary winding l3 operates to cause the induction of an alternating voltage in the transformer secondar winding i5 which is in phase with the alternating 04 is resistance capacity coupled by means of a condenser I05 and a resistance I06 to the input circuits of the triodes II and I2. As illustrated, the contact I01 which in engagement with the resistor I06 is adjustable along the length of the latter and is provided for varying the point of connection of the control electrodes I3 and I6 01' the triodes TI and I2, respectively to the resister I06. The resistor I06 and contact I01 perform a. dual function, namely limit the extent to which the control electrodes 13 and I8 may go positive with respect to their associated cathodes I4 and I1, and also to vary the proportion of the signal impressed upon the control electrodes I3 and I from the anode circuit of the triode 64.

The triodes II and I2 are utilized for supplying energizing current to the winding 34 of the motor l0. As illustrated, anode voltage is supplied the anode circuits of the triodes II and 12 from the secondary winding 3I of the transformer 29. Specifically, the anode IZA of triode H is connected to the left end of the transformer secondary winding 3I and the anode I5 of triode 12 is connected to the right end of winding 3|. The cathodes I4 and 11 are connected together and are connected through themotor winding 34 which, as shown, has a condenser I08 connected thereacross to a center tap on the winding 3i It is noted the cathodes I4 and 11 are also connected to the conductor 43 and thereby to ground 44. It will be noted that the signal voltage from the output circuit of the triode 64 is impressed I simultaneously and equally on the control electrodes I3 and I6 of the triodes II and I2.

This motor driving circuit is disclosed and is being claimed in the Wills U. S. patent application Serial No. 421,173, filed Dec. 1, 1941. For the present purposes it is believed sufficient to note that the motor I0 is preferably so constructed that the impedance of the winding 34 is of the proper value to match the impedance of the anode circuit of the triodes H and I2 when the motor is operating in order to obtain the most eflicient operation. Preferably, the motor is so constructed that it has a high ratio of inductive reactance to resistance, for example, of the order of from 6-1 to 8-1 at the frequency of the energizing current supplied to it. This provides for maximum power during the running condition of the motor with the least amount of heating, and also provides a low impedance path for braking As noted hereinbefore energizing current is supplied to the motor winding 33 from the transformer secondary winding 28 through the condenser 35. The condenser 35 is so selected with respect to the motor winding 33 as to proyide a series resonant circuit having a unity power factor. Due to the series resonant circuit the total impedance of winding 33 is substantially equal to the resistance of the winding 33 and since this resistance is relatively low a large current flow through the winding 33 is made possible. This permits the attainment of maximum power and torque from the motor I 0. Due to the series resonant circuit the current flow through the motor winding 33 is in'phase with the voltage across the terminals of the transformer secondary winding 28. However, the voltage across the motor winding 33 leads the current by substantially 90 because of the inductance of the winding 33.

Energizing current is supplied the motor winding 34 from the transformer secondary winding 3| through the anode circuits of the triodes II and I2 through the circuit previously traced.

The condenser I08 connected in parallel with the winding 34 is so chosen as to provide a parallel resonant circuit having a unity power factor. This parallel resonantcircuit presents a relatively high external impedance and a relatively low local circuit impedance. The relatively high external impedance is approximately the same as the impedance of the anode circuits of the triodes II and I2 and thereby provides efiicient operation. The relatively low or internal circuit impedance approximates the actual resistance of the winding 34, and since this resistance is relatively low the impedance of the local circuit is relatively low.

During the first half cycle of the alternating voltage produced across the terminals of the transformer secondary winding 3I, the anode 12A of the triode TI is rendered positive with respect to the center tap on the winding 3| and during the second half cycle the anode I5 is rendered positive with respect to the center tap on the winding 3|. Accordingly, the triodes II and I2 are adapted to conduct on alternate half cycles.

For the condition when the potentiometric measuring circuit 2 is balanced no voltage is induced in the transformer secondary winding I5 and accordingly the potentials of the control electrodes 50, 54 and 69 f the triodes 41, 43 and 64 remain substantially constant and therefore no signal is impressed upon the control electrodes I3 and .16 of the triodes II and I2.

Under these conditions a pulse of current flows from the anode 12A to the cathode I4 and thereby through the motor winding 34 during the first half cycle of the alternating voltage produced across the transformer secondary winding 3| During the second half cycle a pulse of current flows from the anode I5 to the cathode TI and thereby through the motor winding 34. Since the control electrodes I3 and 18 are connected to gether, and since the potential of these control electrodes remain substantially constant when the potentiometric measuring circuit I is balanced, pulses of equal magnitude flow in the anode circuits of the triodes II and I2 during each succeeding half of the alternating voltage supplied by the transformer secondary winding 3|. Thus, it will be noted that when the potentiometric measurin circuit 2 is balanced pulsating direct current of twice the frequency of the alternating voltage supplied by the transformer secondary winding 3'I is supplied the motor winding 34. When thus energized the motor I0 is not effectively urged to rotation in either direction and remains stationary. Due to the relatively high direct current component of the current then flowing through the motor winding 34 the core structure of the motor I0 tends to become saturated whereby the inductive reactance of the motor winding 34 is relatively small. The condenser I08 is so selected that the condenser in parallel with the motor winding 34 then forms a parallel resonant circuit with the latter. It is noted that such saturation of the core structure of the motor I0 operates to exert an appreciable damping effect on the rotor 23, or in other words an effect tendingto prevent rotation of the rotor 23. Thus, if the rotor 23 had been rotating, such saturation ofthe motor core structure will operate to quickly stop the rotor rotation.

Upon unbalance of the potentiometric measuring circuit 2 the magnitude of the pulses of current flowing in the anode circuit of one triode II or i2 will be increased and the magnitude of the pulses of current flowing in the anode circuit or the other triode decreased. When the motor fleld winding 3d is thus energized the direct current component of the current flowing therethrough is decreased whereby the saturation of the motor core structure and the consequent rotor damping edect is reduced. In addition the alternating component of the current supplied the winding 35 is increased. This alternating component produces an alternating field in the motor core structure which reacm with that es tablished by the motor winding 33 to produce a rotating field in the motor. This rotating field rotates in one direction or the other depending upon the direction of potentiometric unbalance and cfiects actuation of the motor rotor 23 for rotation in a corresponding direction.

'In accordance with the present invention the actuating winding 25 of the current interrupt ing device ll, and the motor windings 33 and 3d are energized from an alternating current source having a frequency which is difierent from the frequency of the current of the supply lines L and L By so energizing the circuit components 2@, 39 and 3d, the possibility of false balance points of the potentiometric network 2 and erratic and unstable operation due to the introduction of extraneous alternating currents of the frequency of the supply lines L and IF or harmonics thereof into the input circuit of the electronic ampliher i from stray alternating fields or other alterhating current sources in the vicinity'of the apparatus is substantially eliminated. In other words, such eatraneously induced currents of the frequency of the pos -er supply lines L and L or any of its harmonic frequencies are rendered lnefiective to cause a shift in the balance point of the potentiometric network It regardless of their phase. Only extraneously induced currents of the frequency utilized to energize the circuit parts 29, 33 and 3% or harmonics thereof can cause dificulty. The frequency of the current employed to energize the parts 28, 33 and 3%. therefore is so chosen that there is little or no possibility of having currents of this ireouency or its harmonics extraneously introduced into the electronic amplifier i.

By way of example, when the frequer cy oi the current of supply lines L and L is 60 cycles per second, the alternating current for energizing the interrupter winding 28 and the motor windings 33 and it may 6 drably hav a frequency of 100 cycles per second. With energizing current of this frequency there may be some slight tendency for the motor iii to tend to oscillate or periodically reverse its direction of rotation when a 60 fill cycle current is impressed on the motor winding but the resultant field is ineffective for energizing the motor It for rotation. Consequently, the motor operation and the correct potentiometer balance point are not upset or disturbed as a result of the introduction of extraneous alternating currents of cycle frequency into the electronic amplifier i. That such operation as obtained may be readily shown mathematically or by vector analysis as will be seen by referring to Figs. 2, 3, 4 and 5.

Figs. 2, 3, 4 and 5 are graphic illustrations of the vector relations between the 60 and 190 cycle fields in the motor 10. Horizontal line l-l in each of these figures designates the direction in which the 60 cycle field builds up, falls off to zero and then builds up in the reverse direction while line 2-2 designates the direction in which the 100 cycle field alternately builds up in reverse directions. Lines l-| and 2-2 are positioned 90 apart since the field established by motor winding 33 is displaced 90 from that produced by motor winding" 2%. at the point oi intersection or" lines 5-5 and 2-2 both of the fields are zero in value,

Referring to Fig. 2, the vector designated by the character A represents the resultant of the 100 and 60 cycle fields when both. of these fields are at their maximum value, which for convenience is the condition chosen as a starting point for the analysis of the reaction of the 109 and 50 cycle fields. For the purpose of this analysis the maximum value of both the so and 1&0 cycle fields are shown as being the same value.

Upon the passage of /460 of a second, the 100 cycle field will have decreased to zero whereas the 60 cycle field will have fallen off only hree fifths of the way toward zero. The result of this action is a clockwise shift of the vector or resultant field from A to B. In successive intervals of /400 of a second the vector or resultant field will shift to C, D and E. The shift of the vector or resultant field produced is approximately 284 for the case under consideration, namely when the maximum value of both the 6G and 190 cycle fields is the same value.

During the next /400 of a second the vector or resultant field decreases to zero without shifting in position and then during the succeeding /400 of a second builds up in the reverse direction as shown in Fig. 3 by the vector 1 The resultant field in successive intervals of /400 of a second shifts in a counter-clockwise direction to G. 1-1, I and J, again shifting through approximately 284.

In the next /400 of a second the resultant field reverse-s its direction of shift as shown in Fig. 2 wherein the resultant field shifts in the cloclwise direction from J to K, while during succeeding" intervals of /400 of a second the resultant field shifts in a clock ise direction to L, M, and N.

During the next /400 of a second the resultant field decreases to zero without shitting in position and in the succeeding /lcc of a second the resultant field builds up in the reverse direction as is indicated in Fig. 5 by the vector (3. The resultant field then, during succeeding intervals of Ace of a second shifts in a counter-clockwise direction to P, Q, R and S, the shift again being approximately 284.

The total time elapsed for this whole procedure is only /100 of a second, during which time the resultant field will have reversed its direction of rotation four times. Since the vector S corresponds exactly to the vector A of Fig. 2, the establishment 'or' a periodically reversing field as described in Figs. 2, 3, 4 and 5 will be continuously repeated. Accordingly, the resultant field in the motor reverses its direction eighty times a second. This rate of reversal is entirely too high for any significant response by the rotor 23 of motor iii, and at most produces only a small am plltude tremor or oscillation of the rotor. In addition there is only a partial revolution of the field in each direction of rotation. As a result of this operation the motor ill does not respond to extraneous alternating currents of supply line frequency, namely 60 cycles, which may be in duced in the potentiometric network or in the electronic amplifier.

As will be recognized by those skilled in the art, the superposition of 60 cycle extraneously induced currents on the cycle motor energizing currents introduced in' the winding 36 upon potentiometric unbalance will produce a component ofcurrent having a frequency of i cycles per second in the motor phase winding 3%. This 40 cycle current component in the motor winding will establi h. a field in the motor which will re: t with the 106 cycle field established In the motor by the 160 cycle energizing current in the motor field winding 23 to produce a resultant ro toting field in the motor which will periodically reverse its direction one hundred times a second and, moreover, will also make only a partial revolution before reversing direction of rotation. That this action is obtained may also be readily shown mathematically or by vector analysis similar to that of Figs. 2, 4 and 5. out such analysis it is noted that as the vertical or we cycle component of the resultant field vector changes from a zero to a maximum value, the 40 cycle or hori'sontal component will only change twe -fifths of the way between zero.

and maximum values.

While such an alternating current of 100 cycles per second for energizing winding of the interrupter i: and the motor windings 33 and 34 may be derived from the alternating urrent power supply conductors L and L by means of any suitable rotary or other frequency converter, I have illustrated in the drawings one suitable type of frequency converter, which may advantageously be so employed. The frequency converter illustrated consists of an electromagnet generally indicated at I09 which includes a core H0 and an electromagnetic coil HI which is wound on the core Hit.

A vibratory reed H2 is positioned substantially in parallel relation with the coil III and is operativcly disposed between a pair of contact arms H3 and I. as read H2 consists of a main blade H5 and an auxiliary blade H8 secured to one end thereof, such blades carrying suitable contacts on their opposite faces. The core lid of the elcctromaguet is bent as at H! and extends adjacent the free end of the read to which ablooi; of magnetic material indicated at H5 secured. The core H0, the reed H2 and the carrying blades H5 and H5 are all supported at one end only in a pillar formed by the ends of such members and alternate layers of insulating material as at H5. The pillar is provided with an aperture through which a bolt 28 extends and by means of which the several components of the pillar are rigidly secured to a supporting base Hi. The bolt I21! is electrically connected with the reed H2 by means of block of electrically conductive and magnetic material 22 which is in threaded engagement with the bolt I20. e

As illustrated the reed H2 is electrically connected by the bolt in and a conductor in to the negative output terminal of the filter H, which terminal is also connected to one side of the electromagnetic coll III. The contact carrying blades H3 and H4 are connected by condoctors (24 and I25, respectively, to the opposite ends of the transformer primary winding 30. The other terminal of the coil III is connected by a conductor I26 to the contact H4. The positive output terminal of the filter 84 is connected by a conductor IZ'I to the center tap on the transformer primary winding 33.

In this arrangement current flows from the negative output terminal of the filter N through the electromagneticcoll I l I, conductors I28 and I to the left end terminal of winding 30 and through winding 30 and conductor 52! to the In carrying positive output terminal of the filter. This current flow operates to energize the coil Hi forming an electromagrwt of the core H0. The pole piece ll? of the core III] will, when energized in this manner, attract the block of magnetic material H8 secured to the end of reed H2. Such attraction of the block IIB moves the reed H2 into contact with the lower contact blade I to thereby short circuit the coil HI through the conductor I25. This reduces the current flow through the (3011 HI so that the strength of the electromagnet is no longer sufiicient to overcome the spring action of the reed H2 whereupon the latter will snap up and over-carry into contact with the upper contact blade I I3.

When the reed H2 makes contact with the upper blade H3 a flow of current will be established through the right half of the transformer primary winding 30 as seen in the drawings but in a direction opposite to the preceding flow of current in the left half of the winding 30. Vibration of the reed ll2.between the contact blades H3 and H4 will, therefore, result in the establishment of an alternating magnetic flux threading the secondary windings 28, 3i and 32 of the transformer 29.

As soon as contact between the reed H2 and the lower contact blade Hi Is broken, the coil III is again energized so that the magnet again asserts its influence on the magnetic block H8 to move the reed back into engagement withthe contact blade H3, thereby maintaining continuous vibration of the reed between the contact blades H3 and H4 at a rate depending upon the natural period of the several moving parts of the apparatus so that each of the moving parts is permitted to vibrate to a certain extent. The apparatus is so designed that the rate of vibration of the several moving parts is that required to produce an alternating current having frequency of approximately 100 cycles per sec- 0nd in the transformer secondary windings 28, 3| and 32. It will be understood, however, that if desired, the apparatus may be designed to produce alternating currents of any other suitable frequency which may advantageously be utilized for energizing the coil 20 of the current lnterrupting device I! and the motor I 0 as required to eliminate the undesirable effects of extraneously induced currents of power line or other frequencies in the input circuit of the electronic amplifier I.

As will be understood from the foregoing description, the embodiment of the present invention disclosed is characterized in that it will not permit shifts in the balanc point of the potenticmetrlc network 2 or erratic or unstable operwhen provisions are made for limiting the magnitude of such extraneous voltages the arrangement disclosed herein will always insure accurate balance of the potentiometric network 2. Such provisions may comprise the introduction of a suitable filter between the transformer secondary winding and the input circuit of the triode 41 of valve 46 for limiting the magnitude of the extraneously introduced currents applied to the input circuit of triode 41, for example. One suitable arrangement for so eliminating or reducing the magnitude of the extraneous voltages induced inthe potentiometric network 2 is disclosed and is being claimed in my copending application Serial Number 466,130, filed November 19, 1942, issued into Patent 2,355,537 on August 8, 1944 It will be apparent that the reversible electrical motor I may be employed to operate a valve I28 positioned in a fuel supply pipe I29 for varying the supply of heating agent tothe furnace to the temperature of which the thermocouple 3 is responsive, or preferably, a separate reversible electrical motor may be so employed. For example, as illustrated in the drawings, a reversible electrical motor I30 having two opposed field windings (not shown) may be used for this purpose. The reversible motor I 30 is mechanically connected in any suitable manner to the valve I28 and is adapted to adjust the latter to its opened and closed position depending upon the direction to which the motor I30 is ener ized for rotation. The mechanical connection of the motor I30 to the valve I28 is such as to increase and decrease the supply of heating agent to the furnace as the temperature of the latter falls below or rises above a predetermined level.

The motor I30 is energized for rotation in one direction or the other, depending upon which of the two opposed field windings is energized, by means of a switch l3l. As shown, current flows from the alternating current supply conductor L through conductor I32 to a switch arm I33 which is insulated from but may be carried by the carriage 8 which carries the potentiometer slidewire cont-act l, thence by either of two opposed contacts I34 or I35, conductors I36 or I31 and One field winding or the other field winding of the motor I30 to the supply conductor 1?. Although not shown the contacts I34 and I35 of the switch III are made adjustable so that both the control point setting and sensitivity of the apparatus may be set in a manner well known in the art.

While in accordance with the provisions of the statutes, I have illustrated and described the best form of my invention now known to me, it will be apparent to those skilled in the art that changes may be made in the form of the apparatus disclosed without departing from the spirit of my invention as set forth in the appended claims, and that certain feature of my invention may sometimes be used to advantage without a corresponding use of other features.

Having now described my invention, what I claim as new and desire to secure by Letters Patent is:

1. Apparatus for measuring the magnitude of a direct current electric potential of unknown magnitude including a 60 cycle per second source of alternating voltage, mean to rectify said al ternating voltage to produce a direct current voltage, means operated by said direct current voltage to produce a 100 cycle per second alternating voltage, means to produce a direct current potential of known magnitude, a circuit to oppose said known direct current potential to said unknown direct current potential to derive a differential potential, circuit interrupting means in said circuit to convert said differential potential into a fluctuating potential, said circuit interrupting means including an operating winding energized by said cycle per second alternating voltage whereby the frequency of said fluctuating potential is 100 cycles per second, amplifying means including electronic valve means to amplify said fluctuating potential, said electronic valve means including an input circuit on which said fluctuating potential is impressed and an output circuit energized by said direct current voltage, means including a two-phase reversible electrical rotating field motor having a pair of phase windings to reduce said differential potential, mean to apply said amplified fluctuating potential to one phase winding of said motor, means to apply said 100 cycle per second alternating voltage to the other phase winding of said motor, and means to cause a phase displacement in the current flow through said last mentioned phase winding with respect to the current flow in the first mentioned phase winding.

2. Apparatus for measuring the magnitude of a direct current electrical potential of unknown magnitude including a source of alternating voltage, means to rectify said alternating voltage to produce a direct current voltage, means operated by said direct current voltage to produce an alternating voltage of frequency different than said first mentioned alternating voltage and different than the harmonic frequencies of the latter, means to produce a direct current potential-of known magnitude, a circuit to oppose said known direct current potential to said unknown direct current potential to derive a differential potential, circuit interrupting means in said circuit to convertsaid differential potential into a fluctuating potential, said circuit interrupting means including an operating winding energized by said second mentioned alternating voltagewhereby. said fluctuating potential is of the same frequenc as said second mentioned alternating voltage, amplifying means including electronic valve means to amplify said fluctuating potential, said electronic valve mean including an input circuit on which said fluctuating potential is impressed and an outmeans to apply said amplified fluctuating poten-,

tial to one phase winding of said motor, means to apply said second mentioned alternating voltage to the other phase Winding of said motor, and means to cause a phase displacement in the current flow through the last mentioned phase winding with respect to the current flow in the first mentioned phase winding.

3. Apparatus for measuring the magnitude of a direct current electrical potential of unknown magnitude including a source of alternating voltage, means to rectify said alternating voltage to produce a direct current voltage, means operated by said direct current voltage to produce an alternating voltage of frequency different than said first mentioned alternating voltage and different than the harmonic frequencies of the latter, means to produce a direct current potential of known magnitude, a circuit to oppose said known direct current potential to said unknown direct current potential to derive a differential potential, circuit interrupting means in said circuit to convert said differential potential into a fluctuating potential, said circuit interrupting means including an operating winding energized by said second mentioned alternating voltage whereby said fluctuating potential is of the same frequency as said second mentioned alternating voltage, and motive structure having a connection with said sec ond mentioned alternating voltage and controlled by said fluctuating potential to reduce said diflerential potential, said motive structure being responsive to the frequency of said fluctuating potential but not to the frequency of said flrst mentioned alternating voltage.

4. Apparatus for measuring the magnitude of a direct current electrical potential of unknown magnitude including a source of alternating voltage, means to rectify said alternating voltage to produce a direct current voltage, means operated by said direct current voltage to produce a fluctuating voltage of frequency difierent than said first mentioned alternating voltage and diiferent than the harmonic frequencies of the latter, means to produce a direct current potential of known magnitude, a circuit to oppose said known direct current potential to said unknown direct current potential to derive a differential potential, means energized by said fluctuating voltage to convert said differential potential into a fluctuatlng potential of one phase or of opposite phase depending upon the polarity of said diflerential potential and of the same frequency as said fluctuating voltage, and phase responsive means controlled by said fluctuating potential to reduce said differential potential, said phase re-v sponsive means being responsive to the frequency of said fluctuating potential but not to the frequency of said first mentioned alternating voltage.

5. Apparatus for measuring the magnitude of a direct electrical potential of unknown magnitude including a source of direct current voltage, means operated by said direct current voltage to produce an alternating voltage, means to produce a direct current potential of known magnitude, a circuit to oppose said known direct current potential to said unknown direct electrical potential to derive a differential potential, circuit interrupting means energized by said alternating voltage and connected in said circuit to convert said diflerential potential into a fluctuating potential, amplifying means including electronic valve means to amplify said fluctuating potential, said electronic valve means including an output circuit energized by said alternating voltage and an input circuit, means to impress said fluctuating potential on the input circuit of said amplifying means, the frequency of said fluctuating potential being the same as that of said alternating voltage but different from the frequency and the harmonics" thereof of an extraneous fluctuating current which may be superimposed on the input circuit of said amplifying means, means including a two-phase reversible electrical rotating field motor having a pair of phase windings to reduce said differential potential, means to apply said amplified fluctuating potential to one phase winding of said motor, means to apply said alternating voltage to the other phase winding of said motor, and means to cause a phase displacement in the current flow through said last mentioned Phase winding with respect to the current flow in the first mentioned phase winding.

6. Apparatus for measuring the magnitude of a direct electrical potential of unknown magnitude including a source of direct current voltage, means operated by said direct current voltage to produce an alternating voltage, means to produce a direct current potential of known magnitude, a"

circuit to oppose said known direct current potential to said unknown direct electrical potential to derive a differential potential, circuit interrupting means energized by said alternating voltage and connected in said circuit to convert said differential potential into a fluctuating potential, means including a two-phase reversible electrical motor having a pair oi phase windings to reduce said differential potential, electronic amplifying means having a preliminary amplifying section and a motor driving section controlled by said preliminary amplifying section, means to apply said fluctuating potential to the input circuit of said preliminary amplifying section, the frequency of said fluctuating potential being the same as that or said alternating voltage but different from the frequency and the harmonics thereof of a fluctuating current which may be superimposed on the input circuit of said preliminary amplifying section, a connection between said direct current voltage and the output circuit of said preliminary amplifying section for energizini; the latter, a connection between said alternating voltage and the output circuit of said motor driving section including one phase winding of said motor, means to apply said alternating voltage to the other phase winding of said motor, and means to cause a phase displacement in the current flow through said last mentioned phase winding with respect to the current flow in the first mentioned phase winding.

'7. Apparatus for measuring the magnitude of a direct electrical potential of unknown magnitude including a source of direct current voltage, means operated by said direct current voltage to produce an alternating voltage, means to produce a direct current potential of known magnitude, a circuit to oppose said known direct current potential to said unknown direct electrical p tential to derive a diilerential potential, means to convert said differential potential into a fluctuating potential of one phase or of opposite phase depending upon the polarity of said difierential potential, means to amplify said fluctuating potential, and phase responsive means having a connection with said alternating voltage and controlled by the amplified quantity of said fluctuating potential to reduce said diflerential poten- I tial, said phase responsive means being responsive to the frequency of said fluctuating potential but not to thefrequency and the harmonics thereof of an extraneous fluctuating potential which may be superimposed on the amplified quantity or said fluctuating potential.

HARRY S. JONES. 

